JP2003294096A - Sprocket for automobile and sprocket supporting device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a sprocket and a sprocket assembly capable of being miniaturized compared with conventional one. <P>SOLUTION: There are provided a sprocket having a plurality of radial involute teeth, a first connecting part which is the first connecting part extending from a first side of the sprocket and having a first connecting structure arranged at an inner perimeter, and a second connecting part which is the second connecting part extending from a second part opposite to the first side of the sprocket, and having a second connecting part having a second connecting structure arranged at an outer perimeter. <P>COPYRIGHT: (C)2004,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a sprocket and a sprocket supporting device which form a part of a bicycle transmission.

[0002]

Bicycles generally include a frame, front and rear wheels, pedals for rotating one or more front sprockets, a plurality of rear sprockets mounted on the rear wheels, the front sprockets and A chain that meshes with one of the plurality of rear sprockets. When two or more front sprockets are provided, a front derailleur is attached to the frame at a position close to the front sprockets, and the front derailleur shifts the chain between the front sprockets. A rear derailleur is mounted on the frame in the vicinity of the plurality of rear sprockets, and chain shifting is performed between the plurality of rear sprockets by the rear derailleur. Normally, the rider will use the front and / or
Or use a manual, electric or hydraulic control to operate the rear derailleur.

By the way, a small bicycle having a foldable frame for facilitating bringing it into public transportation or storing it in the workplace is becoming popular. This kind of bicycle is brought into a crowded place or stored in a crowded place, so that downsizing is required. Therefore, the size of the frame and wheels is minimized. However, in order to achieve the same running speed, the small wheel must rotate faster than a regular wheel. If the pedaling speed is constant and the same traveling speed is to be obtained, a smaller rear sprocket is required. However, the minimum size of the rear sprocket is limited by the diameter of the wheel hub sprocket support structure on which the sprocket is mounted, and the sprocket support structure does not accommodate internal structures such as the ratchet and pawl mechanism. It must be large enough. Therefore, it is impossible to accommodate smaller diameter sprockets in a typical hub.

[0004]

SUMMARY OF THE INVENTION The present invention has been made in view of the above prior art, and an object of the present invention is to provide a sprocket and a sprocket assembly that can achieve miniaturization as compared with the prior art.

[0005]

In one aspect of the present invention, a sprocket portion having a plurality of radially extending teeth and a first connecting portion extending from a first side surface of the sprocket portion, the inner peripheral surface of which is provided. A first connecting part having a first connecting structure, and a second connecting part extending from a second side surface of the sprocket part opposite to the first side surface, the second connecting structure having a second connecting structure on the outer peripheral surface. A sprocket having a coupling part is provided.

In another aspect of the present invention, a sprocket portion having a plurality of radially extending teeth and a first connecting portion extending from a first side surface of the sprocket portion, the first connecting portion being formed on an inner peripheral surface of the sprocket portion. Provided is a sprocket including a first connecting portion having a structure and a second connecting structure arranged on an inner peripheral surface.
A sprocket according to the other aspect is an additional sprocket that includes a sprocket part having a plurality of radially extending teeth and a connecting part extending from a side surface of the sprocket part and having a connecting structure on an outer peripheral surface. Can be used. The outer peripheral connecting structure may mesh with the inner peripheral connecting structure of adjacent splines.

In yet another aspect of the present invention, a sprocket support device for supporting a plurality of sprockets is provided. The sprocket support device has first and second ends and a first tubular member having a first outer peripheral surface for supporting a plurality of first sprocket groups, and first and second ends. And a second tubular member that is separable from the first tubular member and that has a second outer peripheral surface that supports a plurality of second sprocket groups. The second
The first end of the tubular member is connected to the first end of the first tubular member.

[0008]

1 is a side view of a bicycle 10 including a particular form of sprocket assembly according to the present invention. The bicycle 10 includes a handlebar assembly 11
It includes a frame 12 having a front fork 13 that can be rotated by, a front wheel 14 attached to the front fork 13, and a rear wheel 16 attached to a rear portion of the frame 12. A crank spindle 20 is rotatably supported in the lower central portion of the frame 12. The crank spindle 20
At both ends of the crank arm 24 on the left side (in rear view) and the crank arm 26 on the right side.
A pair of crank arms consisting of is mounted non-rotatably. A pedal 22 is attached to each of the pair of crank arms 24 and 26 at their free ends. A front sprocket 28 is assembled to the right crank arm 26, and a chain 30 is meshed with the sprocket 28. A rear hub assembly 32 that supports a plurality (eg, nine as shown in FIG. 2) of rear sprockets 34A to 34I is mounted so as to rotate together with the rear wheel 16, and one of the plurality of rear sprockets 34A to 34I. The chain 30 is meshed with. In order to shift the chain 30 between the plurality of rear sprockets 34A to 34I, the frame 1
A rear derailleur 38 is mounted in the vicinity of the hub assembly 32 at the rear of the unit 2. The rear derailleur 3
8 is operated by a control cable 42 having one end attached to the rear derailleur 38 and the other end attached to a shift control device 44 attached to the handlebar assembly 11.

FIG. 2 is a detailed view of the hub assembly 32. The hub assembly 32 includes a hollow axle 50 that is retained on the frame 12 by a conventional quick release mechanism 54. The quick release mechanism 54 has a pull-out bar 5 that is inserted into the axle 50.
8, a fixed nut 62 screwed on the left side of the pull-out bar 58, and a movable nut 64 arranged on the right side of the pull-out bar 58. The movable nut 64 is
It is moved in the axial direction by a cam mechanism 68 according to a known method, whereby the movable nut 64 and the fixed nut 62 fasten the axle 50 to the frame 12.

The left side portion of the hub shell 72 is an annular outer bearing race 7 mounted on the inner peripheral surface of the hub shell 72.
6, an annular inner bearing race 84 mounted around the axle 50, and a plurality of ball bearings 80 disposed between the outer bearing race 76 and the inner bearing race 84, through a bearing assembly 74. It is rotatably supported by the axle 50. The inner bearing race 84 is held in place on the axle 50 by a locknut 85 and a spacer 86. The right side portion of the hub shell 72 has a plurality of splines 92 which engage with a plurality of splines 96 formed on the left side portion of the inner body 100 so as to be relatively non-rotatable. The right side of the inner body 100 has a threaded surface 104 that mates with a threaded surface 108 that is threaded onto the annular outer bearing race 112 of the bearing assembly 116. The bearing assembly 116 further includes an annular inner bearing race 124 mounted on the axle 50 and a plurality of ball bearings 120 disposed between the outer bearing race 112 and the inner bearing race 124.
The inner bearing race 124 includes the lock nut 12
6 and a spacer 128 hold it in place on the axle 50. As described above, the right side portion of the hub shell 72 and the inner body 100 are rotatably supported by the axle 50 via the bearing assembly 116.

The outer body in the form of a first tubular member 130 having a first end 135 and a second end 137 comprises a plurality of ball bearings 134 and a plurality of ball bearings 1.
It is rotatably supported by the inner body 100 by 38. The ball bearing 134 has an inner peripheral surface 136 of the first end portion 135 of the first tubular member 130.
And the outside of the left side portion of the inner body 100. On the other hand, the ball bearing 138 has the inner peripheral surface 1 of the second end portion 137 of the first tubular member 130.
39 and the outer bearing race 112 of the bearing assembly 116. A plurality of ratchet teeth 140 are formed around the outer peripheral surface of the inner main body 100 in order to mesh with a plurality of ratchet teeth 144 formed on the inner peripheral surface of the first tubular member 130 according to a known method to act as a one-way clutch. Is provided.

The second tubular member 150 is a flange-shaped first member.
It has an end 154 and a second end 158. The second
The first end 154 of the tubular member 150 includes the first tubular member 130 such that the ball bearing 120 is proximate to the left side of the first end 154 of the second tubular member 150.
Is connected to the second end 137 of the. As clearly shown in FIG. 3, in the present embodiment, the first tubular member 1 has a first end 154 of the second tubular member 150.
A threaded outer peripheral surface 162 is provided which is screwed into the threaded inner peripheral surface 166 of the second end 137 of the screw member 30. The outer peripheral surface 162 is further provided with a circumferential groove 170 that engages with the fastener 174. In the present embodiment, the fastener 174 is the first tubular member 130.
Opening 178 with a thread formed in the second end 137
And an allen screw screwed into the groove 170.
w).

As shown in FIG. 3, the first tubular member 130.
Is a plurality of splines 182 formed on the outer peripheral surface 185.
Is equipped with. The plurality of splines 182 includes a plurality of spline protrusions 183 having a plurality of spline grooves 184 interposed therebetween, and the sprockets 34A to 34A-3.
It is adapted to non-rotatably mesh with a plurality of corresponding splines (not shown) formed on the inner peripheral surface of 4F.
As will be described later, such a configuration is also applied to the sprocket 34G. The one spline protrusion 183A and the one spline groove 184A include the sprockets 34A to 34A.
The other spline protrusion 183 and the spline to engage with the spline of the corresponding one sprocket of G and hold the one sprocket in a predetermined rotational position (predetermined circumferential position) with respect to the first tubular member 130. The shape is different from that of the groove 184. The second tubular member 150 supports the sprockets 34G (second sprocket), 34H (third sprocket) and 34I (fourth sprocket),
No spline is formed on the outer peripheral surface 188 of the second tubular member 150. Sprocket 34A-34F (first
The diameter D1 of the outer peripheral surface 185 of the first tubular member 130 that supports the sprockets is sprocket 34G to 34G.
It is larger than the diameter D2 of the outer peripheral surface 188 of the second tubular member 150 supporting I without splines.

In the present embodiment, the sprocket 34
G is directly supported by the second tubular member 150. On the other hand,
The sprockets 34H to 34I are supported by the second tubular member 150 via the sprockets 34G that function as mounting sprockets. Figure 3, Figure 4 (A) and Figure 4 (B)
As shown in FIG.
11) Sprocket part 2 having radially extending teeth 204
00, a tubular first connecting portion 208 extending from the first side wall 212 of the sprocket portion 200, the tubular first connecting portion 208 having a first connecting structure 216 on the inner peripheral surface 220,
A tubular second connecting portion 224 extending from a second side wall 228 of the sprocket portion 200 opposite to the first side wall, the tubular second connecting portion 224 having a second connecting structure 232 on the outer peripheral surface 236; ing. The sprocket part 2
00, the first connecting portion 208, and the second connecting portion 224 are integrally formed.

The first connecting portion 208 has the sprocket 3
4G is connected to the first tubular member 130 in a non-rotatable manner.
The first connecting part 208 includes a plurality of first spline grooves 244.
A plurality of first spline protrusions 240 each of which is interposed
Is provided with a plurality of first splines. The one spline protrusion 240A and the one spline groove 244A are
Corresponding spline groove 18 in first tubular member 130
4A and the spline projection 183A, so as to hold the sprocket 34G in a predetermined rotational position with respect to the first tubular member 130, a shape different from that of the other first spline projection 240 and the first spline groove 244. Has been done. The second connecting portion 224 has a plurality of second spline grooves 25.
A plurality of second spline protrusions 25, each of which is provided with 4
A plurality of second splines having 0 are provided. One second spline protrusion 250A and one second spline groove 2
54A is another second spline protrusion 2 for the following reason.
50 and the second spline groove 254 have different shapes. The second connecting portion 224 has a spline-less inner peripheral surface 258 that engages around the spline-less outer peripheral surface 188 of the second tubular member 150. The diameter D3 of the first inner peripheral surface 220 is larger than the diameter D4 of the second inner peripheral surface 258. The diameter D3 is further larger than the diameter D5 of the second outer peripheral surface 236. If desired, the diameter D5 is determined by the second connecting portion 22.
4 and the side wall 228 of the sprocket portion 200 are measured.

In this embodiment, FIG. 3 and FIG. 5 (A)
Further, as shown in FIG. 5B, the sprocket 34H includes a sprocket portion 300 having a plurality of (for example, 10) radially extending teeth 304, and a tubular connecting portion 308 extending from the first side wall 312 of the sprocket portion 300. It has and.
The connecting portion 308 includes a connecting structure 316 on the inner peripheral surface 320. The sprocket part 300 and the connecting part 308.
Are integrally formed. The connecting portion 308 includes a plurality of splines having a plurality of spline protrusions 340 in which the plurality of spline grooves 344 are provided. The one spline protrusion 340A and the one spline groove 344A are the second connecting portion 2 of the sprocket 34G.
24 corresponding to one second spline groove 254
The other spline protrusion 340 and the spline groove 344 have different shapes so that they can be engaged with the A and one second spline protrusion 250A to hold the sprocket 34H at a predetermined rotational position with respect to the sprocket 34G. There is.

As shown in FIGS. 3, 6A and 6B,
In the present embodiment, the sprocket 34I includes a sprocket portion 400 having a plurality (for example, nine) of radially extending teeth 404, and a tubular connecting portion 408 extending from the first side wall 412 of the sprocket portion 400. ing. The connecting portion 408 includes a connecting structure 416 on the inner peripheral surface 420. The sprocket part 400 and the connecting part 408 are integrally formed. The connecting portion 408 includes a plurality of splines having a plurality of spline protrusions 440 in which the plurality of spline grooves 444 are respectively provided. One spline protrusion 440A and one spline groove 444A
Engages with the corresponding one spline groove 254A and one corresponding spline protrusion 250A provided in the second connecting portion 224 of the sprocket 34G, and the sprocket 34I
Is shaped differently from the other spline projections 440 and spline grooves 444 so that the sprocket 34G can be held at a predetermined rotational position with respect to the sprocket 34G. Sprocket 3
In order to hold 4G to 34I on the second tubular member 150,
The lock nut 460 having the threaded inner peripheral surface 464 is screwed with the threaded outer peripheral surface 468 provided on the second end 158 of the second tubular member 150.

FIG. 7 is a partial exploded view of the components of another embodiment of the sprocket assembly according to the present invention. In the present embodiment, the first tubular member 130,
The second tubular member 150 and the lock nut 460 have the same configuration as in the above-described embodiment. Therefore, detailed description of these members is omitted. The present embodiment is different from the above-mentioned embodiments with respect to the structures of the sprockets 34G 'to 34I'.

In the present embodiment, the sprocket 34
G ′ to 34I ′ are directly supported by the second tubular member 150. As shown in FIGS. 7, 8 (A) and 8 (B),
In the present embodiment, the sprocket 34G ′ includes a sprocket portion 500 having a plurality (for example, 11) of radially extending teeth 504 and a tubular connecting portion 508 extending from a first side wall of the sprocket portion 500. The tubular connection part 508 having the first connection structure 516 on the peripheral surface 520 and the second connection structure 524 provided on the inner peripheral surface of the sprocket part 500 are provided. The sprocket part 500 and the connecting part 508 are integrally formed.

The first connecting portion 508 is provided with the sprocket 34.
G ′ is non-rotatably connected to the first tubular member 130. The first connecting portion 508 includes a plurality of first splines having a plurality of first spline protrusions 540 in which a plurality of first spline grooves 544 are provided, respectively. The one spline protrusion 540A and the one spline groove 544A correspond to the corresponding spline groove 1 formed in the first tubular member 130.
84A and spline projection 183A to engage the other first spline projection 54 so as to hold the sprocket 34G 'in a predetermined rotational position relative to the first tubular member 130.
The first spline groove 544 and the first zero spline groove 544 have different shapes. The second connecting structure 524 includes a plurality of second splines having a plurality of spline protrusions 550 in which a plurality of second spline grooves 554 are respectively provided.
One spline protrusion 550A and one spline groove 55
4 has a different shape from the other spline protrusions 550 and the other spline grooves 554 for the following reason.
The sprocket part 500 includes an inner peripheral surface 558 having no spline which is mounted around the outer peripheral surface 188 having no spline in the second tubular member 150. The diameter D6 of the first inner peripheral surface 520 of the first connection structure 516 is
The diameter is larger than the diameter D7 of the third inner peripheral surface 536 of the second connection structure 524.

As shown in FIGS. 7, 9A and 9B,
In the present embodiment, the sprocket 34H ′ includes a sprocket portion 600 having a plurality of (eg, 10) radially extending teeth 604 and a tubular connecting portion 608 extending from the first side wall 612 of the sprocket portion 600. A first connecting structure 616 provided on an outer peripheral surface 620 of the tubular connecting portion
Tubular connecting portion 608 having a sprocket portion 60
No. 2 second connection structure 62 provided on the inner peripheral surface 636
4 and. The sprocket part 600 and the tubular connecting part 608 are integrally formed.

The first connecting portion 608 is provided with the sprocket 34.
H'is non-rotatably connected to sprocket 34G '. The first connecting portion 608 includes a plurality of first splines having a plurality of first spline protrusions 640 having a plurality of first spline grooves 644 respectively interposed therein. The one spline protrusion 640A and the one spline groove 644A mesh with the corresponding spline groove 554A and the spline protrusion 550A provided in the second connecting structure 524 of the sprocket 34G ′, and the sprocket 34H ′ with respect to the sprocket 34G ′. The size of the first spline protrusion 640 and the size of the other spline groove 644 are different from each other so that the first spline protrusion 640 and the other spline groove 644 can be held at a predetermined rotational position. The second connection structure 624 includes a plurality of second splines having a plurality of second spline protrusions 650 in which the plurality of second spline grooves 654 are respectively interposed. The one second spline protrusion 650A and the one second spline groove 654A are
For the following reason, the other second spline protrusions 650 and the other second spline grooves 654 have different shapes. The connecting portion 608 includes a splineless inner peripheral surface 658 that engages around the splineless outer peripheral surface 188 of the second tubular member 150.

As shown in FIGS. 7, 10 (A) and 10 (B), in the present embodiment, the sprocket 34I 'is
A sprocket part 700 having a plurality of (for example, nine) radially extending teeth 704 and a first sprocket part 700.
A tubular connection 708 extending from the sidewall 712. The connecting portion 708 includes a connecting structure 716 provided on the outer peripheral surface 720, and a splineless inner peripheral surface 758 that engages around the splineless outer peripheral surface 188 of the second tubular member 150. The sprocket part 700 and the connecting part 708 are integrally formed.

The connecting portion 708 is provided with the sprocket 34.
I'is non-rotatably connected to sprocket 34H '. The connecting portion 708 includes a plurality of splines having a plurality of spline protrusions 740 in which the plurality of spline grooves 744 are respectively provided. One spline protrusion 740
A and the one spline groove 744A are provided in the sprocket 34
The second spline groove 654A and the second spline protrusion 650A of the second connection structure 624 at H'to engage the sprocket 34I 'in a predetermined rotational position relative to the sprocket 34H'. The spline protrusion 740 and the other spline grooves 744 have different shapes. The sprocket portion 700 has a knurled side surface 750 that frictionally engages with the lock nut 460.

Although various embodiments of the present invention have been described, various modifications can be made without departing from the spirit and scope of the present invention. For example, the fastener 174 can be omitted. In particular, the first tubular member 130 is made of a material such that the threaded surface 166 of the first tubular member 130 and the threaded surface 162 of the second tubular member 150 can ensure a tightening torque of about 10 times the tightening torque of the lock nut 460. When the 130 and the second tubular member 150 are formed, the fastener 174 can be omitted. Alternatively, as shown in FIG. 11, the fastener 174 may be replaced with a snap ring 900 that engages in a groove 904 formed in the inner peripheral surface 166 ′ of the first tubular member 130. In such a case, the side surface 908 of the second tubular member 150 abuts the snap ring 900. The size, shape, arrangement or orientation of the various components may be changed as desired. It is also possible to provide intermediate structures between the components that are directly connected or abutted against each other. The function of one member can be modified to be performed by two or more members, and vice versa. Furthermore, it is not necessary to have all the effects that exist in a specific form simultaneously. All structures novel to the prior art, whether alone or in combination with other structures, include structural and / or functional concepts embodied in the structure and are distinct inventions made by the inventor. Should be interpreted. That is, the scope of the invention is not limited to the particular forms disclosed.

[0026]

According to the sprocket, the sprocket support device and the sprocket assembly according to the present invention, the size can be reduced as compared with the conventional structure.

[Brief description of drawings]

FIG. 1 is a side view of a bicycle incorporating a sprocket assembly according to an embodiment of the present invention.

FIG. 2 is an enlarged view of a rear hub assembly of the bicycle shown in FIG.

3 is a partial exploded view of the sprocket assembly of the hub assembly shown in FIG.

4 (A) and 4 (B) are respectively a rear view and a front view of a mounting sprocket with 11 teeth which is used in the sprocket assembly.

5 (A) and 5 (B) are respectively a rear view and a front view of a sprocket having 10 teeth used in the sprocket assembly.

6 (A) and 6 (B) are respectively a rear view and a front view of a sprocket having 9 teeth, which is used in the sprocket assembly.

FIG. 7 is a partial exploded view of a sprocket assembly according to another embodiment of the present invention.

8A and 8B are respectively a rear view and a front view of a mounting sprocket with 11 teeth, which is used in the sprocket assembly shown in FIG. 7.

9 (A) and 9 (B) are respectively a rear view and a front view of a sprocket having 10 teeth, which is used in the sprocket assembly shown in FIG. 7.

10A and 10B are respectively a rear view and a front view of a sprocket having 9 teeth, which is used in the sprocket assembly shown in FIG. 7.

FIG. 11 is a partial cross-sectional view showing another method of connecting the first tubular member and the second tubular member.

[Explanation of symbols]

34A-34F 1st sprocket 34G 2nd sprocket (mounting sprocket) 34H 3rd sprocket 34I 4th sprocket 130 1st tubular member 150 2nd tubular member 200 2nd sprocket sprocket part 208 2nd sprocket 1st connection part 224 4th Two sprocket second connecting part 300 Third sprocket sprocket part 308 Third sprocket connecting part 400 Fourth sprocket sprocket part 408 Fourth sprocket connecting part

─────────────────────────────────────────────────── ─── Continuation of the front page (51) Int.Cl. ⁷ Identification code FI theme code (reference) F16H 55/30 F16H 55/30 A

Claims (42)

[Claims] 1. A sprocket portion having a plurality of radially extending teeth, and a first connecting portion extending from a first side of the sprocket portion, the first connecting structure having a first connecting structure disposed on an inner peripheral surface thereof. A first connecting portion and a second connecting portion extending from a second side of the sprocket portion opposite to the first side, the second connecting portion being disposed on the outer peripheral surface.
A sprocket comprising: a second connecting portion having a connecting structure. 2. The sprocket according to claim 1, wherein the first connecting structure has a plurality of splines. 3. The plurality of splines each have a plurality of spline protrusions with spline grooves interposed, and at least one of the plurality of spline protrusions and the spline groove is another plurality of spline protrusions and spline grooves. 3. It has a different shape from
Sprocket described in. 4. The sprocket according to claim 1, wherein the second connecting structure has a plurality of splines. 5. The plurality of splines have a plurality of spline protrusions, each of which has a spline groove, and at least one of the plurality of spline protrusions and the spline groove is another plurality of spline protrusions and spline grooves. 5. It has a different shape from
Sprocket described in. 6. The sprocket according to claim 1, wherein the sprocket part, the first connecting part and the second connecting part are integrally formed. 7. The sprocket according to claim 1, wherein the first and second connecting portions have a tubular shape. 8. The sprocket according to claim 7, wherein the diameter of the inner peripheral surface of the first connecting portion is larger than the diameter of the inner peripheral surface of the second connecting portion. 9. The sprocket according to claim 8, wherein the diameter of the inner peripheral surface of the first connecting portion is larger than the diameter of the outer peripheral surface of the second connecting portion. 10. The sprocket according to claim 9, wherein a diameter of an outer peripheral surface of the second connecting portion is measured at an intersection of the second connecting portion and a side wall of the sprocket portion. 11. The first connecting portion has an inner peripheral surface without splines.
The sprocket according to any one of 1. 12. A sprocket portion having a plurality of radially extending teeth, and a connecting portion extending from a first side of the sprocket portion, the connecting portion having a connecting structure disposed on an outer peripheral surface thereof. A sprocket characterized by being present. 13. The sprocket according to claim 12, wherein the connecting portion has a tubular shape. 14. The sprocket part and the connecting part are integrally formed.
The sprocket according to item 3. 15. The sprocket according to claim 12, wherein the connecting portion has an inner peripheral surface without splines. 16. The sprocket according to claim 12, wherein the connecting structure has a plurality of splines. 17. The plurality of splines each have a plurality of spline protrusions in which spline grooves are provided, and at least one of the plurality of spline protrusions and the spline groove is another plurality of spline protrusions and spline grooves. 17. It has a different shape from
Sprocket described in. 18. A sprocket part having a plurality of radially extending teeth, and a first connecting part extending from a first side of the sprocket part, the first connecting structure having a first connecting structure arranged on an inner peripheral surface thereof. A sprocket comprising one connecting portion and a second connecting structure arranged on an inner peripheral surface. 19. The sprocket according to claim 18, wherein the second connecting structure is disposed on an inner peripheral surface of the sprocket part. 20. The sprocket part and the first connecting part are integrally formed.
The sprocket according to item 9. 21. The sprocket according to claim 18, wherein the first connecting structure has a plurality of splines. 22. Each of the plurality of splines has a plurality of spline projections in which a spline groove is provided, and at least one of the plurality of spline projections and the spline groove is another plurality of spline projections and a spline groove. 3. It has a different shape from
The sprocket described in 1. 23. The sprocket according to claim 18, wherein the second connecting structure has a plurality of splines. 24. The plurality of splines each have a plurality of spline protrusions with spline grooves interposed, and at least one of the plurality of spline protrusions and the spline groove is another plurality of spline protrusions and spline grooves. 3. It has a different shape from
The sprocket according to item 3. 25. The sprocket according to claim 18, wherein the first connecting portion has a tubular shape. 26. The sprocket according to claim 25, wherein the diameter of the inner peripheral surface of the first connecting portion is larger than the diameter of the inner peripheral surface of the portion having the second connecting structure. . 27. A device for supporting a plurality of sprockets, the first tubular member having a first end and a second end and having a first outer peripheral surface supporting a plurality of first sprockets. And a second tubular member having a first end portion and a second end portion and having a second outer peripheral surface that supports a plurality of second sprocket groups, and is separable from the first tubular member. A second tubular member, the first end of the second tubular member being the second tubular member of the first tubular member.
A sprocket support device characterized in that it is connected to an end portion. 28. The sprocket support device according to claim 27, wherein a diameter of the first outer peripheral surface is different from a diameter of the second outer peripheral surface. 29. The sprocket support device according to claim 27, further comprising a first bearing race arranged on an inner peripheral surface of the first tubular member. 30. The sprocket support device of claim 29, wherein the first bearing race is disposed at a first end of the first tubular member. 31. The sprocket support device according to claim 27, further comprising a second bearing race arranged on an inner peripheral surface of the second tubular member. 32. The outer peripheral surface of the first end portion of the second tubular member is connected to the inner peripheral surface of the second end portion of the first tubular member. The sprocket support device according to claim 1. 33. The fastener according to claim 27, further comprising a fastener that connects the first end of the second tubular member to the second end of the first tubular member. The sprocket support device described. 34. The first end of the second tubular member has a threaded surface that mates with the threaded surface of the second end of the first tubular member. The sprocket support device according to any one of 27 to 33. 35. The outer peripheral surface of the first end portion of the second tubular member has a screw portion that is screwed into a screw portion provided on the inner peripheral surface of the second end portion of the first tubular member. 35. The sprocket support device according to claim 34, wherein: 36. A plurality of first sprocket groups disposed along the circumferential direction on the first outer peripheral surface of the first tubular member so as to support at least one sprocket of the plurality of first sprocket groups such that they cannot rotate relative to each other. The sprocket support device according to any one of claims 27 to 35, further comprising one spline. 37. The sprocket according to claim 36, wherein the second outer peripheral surface of the second tubular member supporting at least one sprocket of the plurality of second sprocket groups is splineless. Support device. 38. The plurality of first splines are configured to support all of the plurality of first sprocket groups, and the spline-less outer peripheral surface of the second tubular member supports all of the plurality of second sprocket groups. 38. The sprocket support device of claim 37 configured to support. 39. The diameter of the outer peripheral surface of the first tubular member supporting at least one sprocket of the plurality of first sprocket groups has a diameter of the second supporting sprocket of at least one of the plurality of second sprocket groups. 39. The sprocket support device according to claim 38, wherein the diameter is larger than the diameter of the outer peripheral surface of the tubular member. 40. The plurality of first splines each have a plurality of first spline protrusions in which first spline grooves are provided, and at least one of the plurality of first spline protrusions and the first spline groove is formed. The sprocket support device according to any one of claims 36 to 39, wherein the sprocket support device has a different shape from the other plurality of first spline protrusions and the first spline grooves. 41. A mounting sprocket further comprising: a sprocket portion having a plurality of radially extending teeth, and a first connecting portion extending from a first side of the sprocket portion, A first connecting part having a first connecting structure having a plurality of splines that engage with the first spline of the first connecting part, and a second connecting part extending from a second side of the sprocket part opposite to the first side. The sprocket supporting device according to any one of claims 36 to 40, further comprising a second connecting portion having a second connecting structure on an outer peripheral surface thereof. 42. A mounting sprocket is further provided, wherein the mounting sprocket comprises a sprocket portion having a plurality of radially extending teeth, and a first connecting portion extending from a first side of the sprocket portion. A first connecting part having a first connecting structure having a plurality of splines that engage with the first sprocket and a second connecting structure provided on an inner peripheral surface of the first connecting part. The sprocket support device according to any one of 36 to 40.